US3574738A - Process of synthesizing urea - Google Patents
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- US3574738A US3574738A US787059A US3574738DA US3574738A US 3574738 A US3574738 A US 3574738A US 787059 A US787059 A US 787059A US 3574738D A US3574738D A US 3574738DA US 3574738 A US3574738 A US 3574738A
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07C—ACYCLIC OR CARBOCYCLIC COMPOUNDS
- C07C273/00—Preparation of urea or its derivatives, i.e. compounds containing any of the groups, the nitrogen atoms not being part of nitro or nitroso groups
- C07C273/02—Preparation of urea or its derivatives, i.e. compounds containing any of the groups, the nitrogen atoms not being part of nitro or nitroso groups of urea, its salts, complexes or addition compounds
- C07C273/04—Preparation of urea or its derivatives, i.e. compounds containing any of the groups, the nitrogen atoms not being part of nitro or nitroso groups of urea, its salts, complexes or addition compounds from carbon dioxide and ammonia
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- the present invention relates to improvements in the preparation of urea from liquid ammonia and gaseous carbon dioxide or compounds thereof. More particularly, it relates to a method for preventing or inhibiting corrosion of the equipment employed in such urea synthesis reactions.
- Urea is generally synthesized by reacting a mixture of ammonia and carbon dioxide at elevated pressure and temperature in a high pressure equipment. Thereby ammonia and carbon dioxide react to form ammonium carbamate which is then dehydrated to urea.
- the rst reaction step is more or less complete.
- the second reaction step is incomplete and only part of the carbamate is dehydrated to urea. Excess ammonia above the stoichiometric amount in relation to carbon dioxide promotes dehydration of carbamate to urea.
- the urea synthesis melt usually containing urea, water, unreacted ammonium carbamate, and excess ammonia, is very corrosive and attacks very readily the synthesis apparatus which usually consists of stainless steel or other chromium alloys. It is common practice to feed oxygen or oxygen containing gas such as air, to the urea synthesis reactor with the purpose of -maintaining the stainless steel surface of the apparatus in contact with the urea synthesis melt sufiiciently passivated and thus more resistant -to corrosion.
- the rate of corrosion of the urea synthesis vessel walls is usually monitored by checking the content of iron in the urea product solution by chem-ical analysis.
- the iron content in the solution was about 0.4 p.p.m.
- the turbidity of the urea'product solution is usually caused by the urea byproducts, by the higher urea polymers, by nitrites, nitrates, and other compounds which are formed in a urea synthesis reactor in the presence of an excessive amount of oxygen or air. ln Example 1 the turbidity of the solution was about p.p.m. APHA Standard.
- the method according to the present invention comprises carrying out the urea synthesis under speciiic conditions, namely by operating at a pressure lbetween about 180 atm. gauge and about 240 atm. gauge and at a temperature between about 185 C. and about 195 C. whereby oxygen in the form of air is admixed to the liquid ammonia in an amount which is equivalent to between about 0.6 mole and about 0.85 mole of oxygen per 1,000 moles of carbon dioxide fed to the reactor corresponding to 0.06% to 0.085%, by volume, calculated for the carbon dioxide.
- the overall mole ratio of ammonia to carbon dioxide in the urea synthesis reactor mixture is between 3.5 and 4.2:1 and preferably 3.8:1.
- Water is also present in the reaction mixture in a molar ratio of water to carbon dioxide Ibetween about 0.5 to 0.7 :1 and preferably of 0.6: l.
- the oxygen or air is not introduced into the gaseous carbon dioxide as in the known processes but is admixed to the stream of liquid ammonia prior to the introduction into the reactor.
- Such oxygen or air is completely dissolved in the liquid ammonia before it reacts with carbon dioxide, and the tendency of such oxygen or air to escape upwards through the reactor is minimized. For this reason the reactor bottom section is much more protected against corrosion than when oxygen or air is admixed to the gaseous carbon dioxide prior to introduction into the reactor.
- a further advantage of the present invention is that the unreacted carbamate is recovered from the reactor effluent. It is recycled back to the reactor as an ammoniacal aqueous solution of ammonium carbamate for total recovery and conversion into urea, along with fresh liquid ammonia and gaseous carbon dioxide reactor feed streams.
- the apparatus used in the urea synthesis process according to the present invention is the conventionally used reactor of stainless steel.
- a preferred stainless steel is composed, for instance, of 16% to 29% of chromium, 6% to 14% of nickel, 0% to 4% of molybdenum, and less than 0.1% of carbon.
- Other chromium-nickel steels may also be used, preferably such steels having at least 16% of chromium and 8% of nickel.
- the urea synthesis equipment may also consist of other material lined with such stainless steel.
- Other metals than molybdenum may be present in the nickel-chromium stainless steel apparatus such as zirconium, cobalt, tungsten, manganese, copper, and others.
- purified carbon dioxide is conducted through pipe 1 to compressor 2 wherein it iS compressed to the required pressure. It is then passed through pipe 3 into after-cooler 4 wherein it is indirectly cooled by cooling water introduced into the shell side of after-cooler 4 through pipe 5 and discharged therefrom through pipe 6. Thereafter, the cooled compressed carbon dioxide is passed through pipe 7 into oil separator 8 wherein condensed oil and other impurities are separated from the carbon dioxide and are discharged through pipe 9. The purified compressed carbon dioxide is then conducted into the lower part of reactor 11.
- Liquid ammonia is pumped by pump 13 through pipes 12 and 14 into heater 15 wherein it is indirectly heated by steam introduced through pipe 16 into the shell side of heater 15.
- the steam condensate is discharged through pipe 17.
- the heated liquid ammonia leaves heater 15 through pipe 18 and is mixed in pipe 19 with compressed air in the required amount.
- Air is conducted into. air compressor 21 through pipe 20.
- the compressed air is conducted through pipe 22 into after-cooler 23, wherein it is cooled by cooling water passing through the shell side of after-cooler 23.
- the cooled air is discharged from the after-cooler Y23 through pipe 26 and is conducted to oil separator 36 and through pipe 37 to pipe 19 where it is mixed with and dissolved in the liquid ammonia discharged from heater 15 through pipe 18. Condensed oil and other impurities are discharged through pipe 38.
- the liquid ammonia and air mixture is introduced through pipe 19 into the lower part of reactor 11.
- pipe 35 there is introduced into reactor 11 the recycled ammonium carbamate solution formed in the decomposition, absorption, and ammonia and carbon dioxide recovery section 30 which will be described hereinafter.
- the reactor 11 operates adiabatically at a temperature between about 180 C. and about 195 C. and at a pressure between about 180 atmospheres gauge and about 240 atmospheres gauge.
- the gaseous carbon dioxide fed to the reactor reacts instantaneously and totally with the stoichiometric amount of ammonia to form ammonium carbamate.
- the exothermic heat of reaction is utilized to adiabatically maintain the reactor mixture at the reaction temperature.
- the reactor etlluent which contains urea, unreacted ammonium carbamate, excess ammonia, water, and air completely dissolved in the reactor etlluent solution is delivered through pipe 27, pressure control valve 28, and pipe 29 into the recovery unit 30 wherein the unreacted carbamate is decomposed to carbon dioxide and ammonia which are separated from the urea solution.
- the urea solution is discharged through pipe 32.
- Ammonia and carbon dioxide are thereafter recondensed to ammonium carbamte which is redissolved in water with part of the excess ammonia and is recycled for complete utilization back into reactor 11 through pipe 31, carbamate pump 34, and pipe 35.
- the remaining portion of excess ammonia is recycled back through pipe 33 into pipe 12 to join the main stream of fresh liquid ammonia fed into the reactor.
- 'I'he material of which the urea synthesis equipment is constructed is stainless steel or other chromium-nickel steels containing, for instance, from 16% to 20% of chromium, 8% to 14% of nickel, and 1.75% to 4% of molybdenum and zirconium.
- the three components are reacted in reactor 11 at a temperature of 190 C. and a pressure of 210 atmospheres gauge.
- the reactor eflluent consists of a gaseous phase of the following composition:
- the gaseous 'and liquid reactor effluents are delivered to the ammonia-carbon dioxide recovery section 30.
- the recondensed ammonium carbamate solution which is recycled from the recovery section 30 to the reactor 11 is composed of Parts Carbon dioxide 7,400 Ammonia 9,950 Water 5,800
- the oxygen ratio in the reaction mixture is moles O2 3 1000 moles CO2-
- the reactor effluent has NH3 a. molar ratio of CO2 4 and H2O a molar ratio of -0.72
- the conversion rate is 62%.
- the iron content of the reactor etlluent is 0.4 ppm. and the turbidity is p.p.m. APHA Standard.
- a ratio of three moles of oxygen to 1000 moles of carbon dioxide, corresponding to 0.3%, by volume, of oxygen calculated for carbon dioxide freshly introduced into the apparatus yields a urea product of a satisfactory iron content 4but of a relatively high turbidity and with a relatively low conversion rate.
- the reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
- the reactor eiliuent is a liquid of the following composition:
- Said liquid eiuent is delivered to the ammonia-carbon dioxide recovery section 30.
- the oxygen ratio in the reaction mixture is moles of O2 0 71 1000 moles of fresh CO2-
- the reactor eiuent has NH3 a molar rat-1o of CO2 4 and H2O a molar rat1o of 0 0-2-071 thereby excluding the synthesis Water.
- the conversion rate is 70%.
- the iron content of the reactor eluent is 0.5 p.p.m. and the turbidity is 35 p.p.m. APHA Standard.
- the conversion rate is appreciably higher, namely about 13% higher, and the turbidity of the resulting urea solution is Within the commercially acceptable range of about 35 p.p.m. APHA Standard in comparison to the lower conversion rate and the considerably higher turbidity of the urea solution produced according to Example 1 with a considera'bly higher oxygen ratio.
- the corrosion rate of the urea synthesis apparatus walls is also very low and about as low as when admixing larger amounts of oxygen and the iron content of the reactor eluent is about the same as that of Example 1.
- the reaction temperature is 200 C. and the reaction pressure 320 atmospheres gauge.
- the liquid reactor efuent is composed as follows:
- Said euent is delivered to the ammonia-carbon dioxide recovery section 30.
- the oxygen ratio in the reaction mixture is moles O2 0 2 1000 moles CO2-
- the reactor effluent has a. molar ratio of and thereby excluding the synthesis water.
- the conversion rate is 72%.
- the iron content of the reactor effluent is 15 p.p.m. and the turbidity is 20 p.p.m. APHA Standard.
- the reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
- the liquid reactor eiuent is composed of Parts Urea 16,800 Ammonium carbamate 10,281 Ammonia 12,599 Water u 9,500 Air 27 Total liquid effluent 49,207
- Said efuent is delivered to the ammonia-,carbon dioxide recovery section 30. l p
- the conversion rate is 68%.
- the -iron content of thereactor eiiiuent is 0.5 p.p.m. and the turbidity is 30 p.p.m. APHA Standard.
- Example 2 shows that by proceeding according to the present invention the conversion rate is considerably increased and the turbidity is markedly decreased compared iwith the respective data obtained when proceeding according to 'Example 1, i.e. according to U.S. 'Patent No. 2,727,069', while compared with the procedure according to U.S. Patent No. 3,137,- 724 the anticorrosive effect is many times improved.
- the oxygen ratio in the reaction mixture is moles O2 0 2 1000 moles CO2-
- the reactor eluent has NH3 a molar ratio of CO2-4 and H2O a molar ratio of -Cz 0.71
- the conversion rate is The iron content of the reactor effluent is l5 p.p.m. and the turbidity is 20 p.p.m. APHA Standard.
- the reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
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Abstract
CORROSION OF STAINLESS STEEL EQUIPMENT USED FRO THE SYNTHESIS OF UREA FROM AMMONIA AND CARBON DIOXIDE IS SUBSTANTIALLY PREVENTED BY DISSOLVING OXYGEN OR AIR IN THE LIQUID AMMONIA FEED PRIOR TO ITS INTRODUCTION INTO THE REACTOR. UREA SYNTHESIS IS EFFECTED UNDER SPECIFIC REACTION CONDITIONS SUCH AS OPERATION WITH A SPECIFIC RATIO OF OXYGEN, AMMONIA, AND WATER TO CARBON DIOXIDE AS WELL AS UNDER SPECIFIC TEMPERATURE AND PRESSURE CONDITIONS WHEREBY A HIGH CONVERSION RATE IS ACHIEVED AND THE RESULTING UREA PRODUCT IS OF LOW TURBIDITY AND LOW IRON CONTENT.
Description
April 13, 1971 LMAvRovlc PROCESS OF SYNTHESlZING UREA Filed Dec. 26, 1968 M umJOoummPu H Mommwmmoo NOU mmwn \U @u Am 12.67. m
w..m Nm\ TIL l I l I l IIIIIL mm JM. QNU M mmJooommh m .U *ML mw ommllmmoo WN NN A GENT United States Patent Oiiice 3,574,738 PROCESS OF SYNTHESIZING UREA Ivo Mavrovic, 530 E. 72nd St., New York, N.Y.
Filed Dec. 26, 1968, Ser. No. 787,059 Int. Cl. C07c 127/00 U.S. Cl. 260--555 4 Claims ABSTRACT OF THE DISCLOSURE BACKGROUND `OF THE INVENTION (1) Field of the invention The present invention relates to improvements in the preparation of urea from liquid ammonia and gaseous carbon dioxide or compounds thereof. More particularly, it relates to a method for preventing or inhibiting corrosion of the equipment employed in such urea synthesis reactions.
(2) Description of the prior art Urea is generally synthesized by reacting a mixture of ammonia and carbon dioxide at elevated pressure and temperature in a high pressure equipment. Thereby ammonia and carbon dioxide react to form ammonium carbamate which is then dehydrated to urea. The rst reaction step is more or less complete. The second reaction step, however, is incomplete and only part of the carbamate is dehydrated to urea. Excess ammonia above the stoichiometric amount in relation to carbon dioxide promotes dehydration of carbamate to urea.
The urea synthesis melt, usually containing urea, water, unreacted ammonium carbamate, and excess ammonia, is very corrosive and attacks very readily the synthesis apparatus which usually consists of stainless steel or other chromium alloys. It is common practice to feed oxygen or oxygen containing gas such as air, to the urea synthesis reactor with the purpose of -maintaining the stainless steel surface of the apparatus in contact with the urea synthesis melt sufiiciently passivated and thus more resistant -to corrosion.
It is customary to feed air to the reactor for this purpose in an amount which is equivalent to about 2 moles to 3 moles of oxygen per 1,000 moles of carbon dioxide supplied corresponding to about 0.15% to 0.23% of oxygen in the carbon dioxide.
It has been found that although this relatively large amount of oxygen is beneliical with respect to preventing corrosion of the stainless steel reactor walls exposed to the corrosive urea melt, the large excess of Oxygen therein is quite detrimental with respect to the conversion rate of carbamate to urea and thus to the overall yield of urea. The relatively large amount of air as used heretofore is not completely dissolved in the urea synthesis mixture under the urea synthesis conditions and tiows in the gaseous state through hte urea synthesis apparatus. Due to the relatively high carbamate vapor pressure existing as ammonia and carbon dioxide in the reactor, the gaseous undissolved air phase will carry along a large amount 0f gaseous ammonia and carbon dioxide at `the ratio of about Patented Apr. 13, 1971 200 moles to 300 moles of ammonia and carbon dioxide per one mole of oxygen in the air (see Example 1 given hereinafter). Due to the fact that urea is formed by dehydration of the carbamate and that carbon dioxide must first react to form carbamate which is then converted to urea, the overall loss in carbon dioxide conversion t0 urea consequently will be proportional to the amount of carbon dioxide which did not react to form carba-mate and which is maintained in the gaseous phase due vto the presence of gaseous air. Thus the known process of preventing corrosion of the urea synthesis apparatus and equipment 4by the addition of large amounts of oxygen or air has the great disadvantage that the conversion rate of the reaction mixture is considerably reduced.
It has been -noted that the relatively high air rate (see Example l given hereinafter) prevented the corrosion of the stainless steel apparatus according to the tea-ching of U.S. Pat. No. 2,727,069, but it also caused the turbidity of the solution to increase quite considerably above the average normal value obtained with less air feed to the reactor, and it also caused the conversion per pass of carbon dioxide to urea to decrease.
The rate of corrosion of the urea synthesis vessel walls is usually monitored by checking the content of iron in the urea product solution by chem-ical analysis. In the above mentioned example the iron content in the solution was about 0.4 p.p.m.
The turbidity of the urea'product solution is usually caused by the urea byproducts, by the higher urea polymers, by nitrites, nitrates, and other compounds which are formed in a urea synthesis reactor in the presence of an excessive amount of oxygen or air. ln Example 1 the turbidity of the solution was about p.p.m. APHA Standard.
It has also been noted that by feeding air to the urea synthesis reactor at a rate which is lower than about 0.5 mole of oxygen per 1000 moles of carbon dioxide and operating at a pressure between 300 and 350 atmospheres according to the teaching of U.S. Patent No. 3,137,724 (see Example 3 given hereinafter), the turbidity of the reactor effluent solution was considerably lower than in the eliiuent solution obtained according to Example 1. At the same time, however, the corrosion rate of the urea synthesis reactor vessel walls increased by a factor of about 37.5, compared to the corrosion rate when proceeding according to said example. The iron content of the urea product solution was about 15 p.p.m.
It is very common in the industry that the gaseous carbon dioxide used to produce urea s contaminated with sulfur compounds, which are very much detrimental in combating the corrosion rate of the urea synthesis apparatus walls. Such contaminated carbon dioxide is usually passed through a sulfur removal apparatus before being used to synthesize urea. However, minute traces of sulfur compounds, in the order of magnitude of about 0.1-0.2 p.p.m., usually still remain present in the gaseous carbon dioxide due to the inability of the sulfur removal apparatus to operate in practice at an absolute 100% efficiency.
It was noted that when such purified gaseous carbon dioxide which still contains practically undetectable amounts of sulfur compounds in the range of less than 1 p.p.m. of sulfur, was used to synthesize urea at an oxygen level in the synthesis melt of less than about 0.5 mole of oxygen per 1000 moles of fresh carbon dioxide, the rate of corrosion of the urea synthesis apparatus walls and thus the concentration of iron in the reactor effluent urea solution increased quite rapidly by a factor of about 20 or 30.
It is customary that the oxygen or air is admixed to the carbon dioxide stream prior to compression. This procedure, however, has a number of disadvantages. When air is introduced into the reactor bottom via the gaseous carbon dioxide it is not immediately and completely dissolved into the reactor melt. This undissolved portion of air escapes upwardly very rapidly. As a result thereof the bottom part of the reactor does not receive a suicient amount of oxygen and thus will be corroded. Furthermore, a considerable loss in conversion occurs because the upwardly escaping air carries along a considerable amount of ammonia gas and carbon dioxide, which thus are not given a sufficient residence time in the reactor to be converted to urea.
SUMMARY OF THE INVENTION It is one object of the present invention to provide a simple and effective method of protecting the metallic surfaces of the urea synthesis equipment against corrosion without any substantial reduction in conversion rate and without substantially increasing the turbidity of the urea reactor effluent solution.
Other objects of the present invention and advantageous features thereof will become apparent as the description proceeds.
In principle the method according to the present invention comprises carrying out the urea synthesis under speciiic conditions, namely by operating at a pressure lbetween about 180 atm. gauge and about 240 atm. gauge and at a temperature between about 185 C. and about 195 C. whereby oxygen in the form of air is admixed to the liquid ammonia in an amount which is equivalent to between about 0.6 mole and about 0.85 mole of oxygen per 1,000 moles of carbon dioxide fed to the reactor corresponding to 0.06% to 0.085%, by volume, calculated for the carbon dioxide. The overall mole ratio of ammonia to carbon dioxide in the urea synthesis reactor mixture is between 3.5 and 4.2:1 and preferably 3.8:1.
Water is also present in the reaction mixture in a molar ratio of water to carbon dioxide Ibetween about 0.5 to 0.7 :1 and preferably of 0.6: l.
Furthermore, according to the present invention the oxygen or air is not introduced into the gaseous carbon dioxide as in the known processes but is admixed to the stream of liquid ammonia prior to the introduction into the reactor. Such oxygen or air is completely dissolved in the liquid ammonia before it reacts with carbon dioxide, and the tendency of such oxygen or air to escape upwards through the reactor is minimized. For this reason the reactor bottom section is much more protected against corrosion than when oxygen or air is admixed to the gaseous carbon dioxide prior to introduction into the reactor.
A further advantage of the present invention is that the unreacted carbamate is recovered from the reactor effluent. It is recycled back to the reactor as an ammoniacal aqueous solution of ammonium carbamate for total recovery and conversion into urea, along with fresh liquid ammonia and gaseous carbon dioxide reactor feed streams.
Addition of the small amount of oxygen of between about 10.6 mole and about 0.85 mole of oxygen dissolved in the liquid ammonia feed per 1000 moles of fresh carbon dioxide introduced into the reactor not only causes the stainless steel urea synthesis apparatus to retain its excellent anticorrosive properties, but also improves the overall urea yield by to 20% compared to the. yield achieved when feeding air together with the carbon dioxide into the urea synthesis reactor in an amount which is equivalent to 2 moles to 3 moles of oxygen per 1,000 moles of carbon dioxide fed into the reactor (see Examples 1 and 2 given hereinafter).
'Ihe above mentioned essential features of the present invention, namely (a) the presence in the urea synthesis system of an amount of oxygen between about 0.6 mole and 0.85 mole of oxygen per 1000 moles of carbon dioxide (b) which oxygen is admixed to and dissolved in the liquid ammonia before feeding the ammonia into the reactor (c) carrying out the reaction at a relatively low ternperature between about C. and about 195 C. and preferably at C., and
(d) at a relatively low pressure between about 180 atmospheres gauge and about 240 atmospheres gauge and preferably at 210 atmospheres gauge (e) with a ratio of ammonia to carbon dioxide between 3.5-4.2:1 and (f) in the presence of water in a ratio of water to carbon dioxide between about 0.5 mole and about 0.7 moles of water to 1 mole of carbon dioxide,
(g) recovering the unreacted carbamate from the effluent of the reactor and (h) recycling said recovered carbamate in the form of an aqueous ammoniacal solution are responsible not only for (1) substantially preventing corrosion of the urea synthesis apparatus `without any substantial decrease in overall carbon dioxide conversion to urea per pass in the reactor, but also for (2) an almost quantitative utilization of the fresh carbon dioxide fed to the urea synthesis reactor due to the recycling of the unreacted carbamate,
(3) maximum utilization of the reactor space, and
(4) the production of urea of low turbidity and (5) of a low iron content.
It is quite surprising that addition of such a small amount of oxygen or air to the liquid ammonia feed and operation at a relatively low temperature and pressure in the so-called liquid carbamate recycle system not only substantially prevents corrosion of the urea synthesis apparatus but also considerably increases the conversion rate and the overall yield of urea of excellent properties, compared to the procedure according to the prior art in which a relatively high amount of oxygen or air was used to prevent the corrosion of the urea synthesis apparatus.
The apparatus used in the urea synthesis process according to the present invention is the conventionally used reactor of stainless steel. A preferred stainless steel is composed, for instance, of 16% to 29% of chromium, 6% to 14% of nickel, 0% to 4% of molybdenum, and less than 0.1% of carbon. Other chromium-nickel steels may also be used, preferably such steels having at least 16% of chromium and 8% of nickel. Of course, the urea synthesis equipment may also consist of other material lined with such stainless steel. Other metals than molybdenum may be present in the nickel-chromium stainless steel apparatus such as zirconium, cobalt, tungsten, manganese, copper, and others.
BRIEF DESCRIPTION OF THE DRAWING The present invention will be further described by reference to the attached drawing which illustrates diagrammatically the equipment used for urea synthesis according to the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIG. l, purified carbon dioxide is conducted through pipe 1 to compressor 2 wherein it iS compressed to the required pressure. It is then passed through pipe 3 into after-cooler 4 wherein it is indirectly cooled by cooling water introduced into the shell side of after-cooler 4 through pipe 5 and discharged therefrom through pipe 6. Thereafter, the cooled compressed carbon dioxide is passed through pipe 7 into oil separator 8 wherein condensed oil and other impurities are separated from the carbon dioxide and are discharged through pipe 9. The purified compressed carbon dioxide is then conducted into the lower part of reactor 11.
Liquid ammonia is pumped by pump 13 through pipes 12 and 14 into heater 15 wherein it is indirectly heated by steam introduced through pipe 16 into the shell side of heater 15. The steam condensate is discharged through pipe 17. The heated liquid ammonia leaves heater 15 through pipe 18 and is mixed in pipe 19 with compressed air in the required amount.
Air is conducted into. air compressor 21 through pipe 20. The compressed air is conducted through pipe 22 into after-cooler 23, wherein it is cooled by cooling water passing through the shell side of after-cooler 23. The cooled air is discharged from the after-cooler Y23 through pipe 26 and is conducted to oil separator 36 and through pipe 37 to pipe 19 where it is mixed with and dissolved in the liquid ammonia discharged from heater 15 through pipe 18. Condensed oil and other impurities are discharged through pipe 38.
The liquid ammonia and air mixture is introduced through pipe 19 into the lower part of reactor 11. Through pipe 35 there is introduced into reactor 11 the recycled ammonium carbamate solution formed in the decomposition, absorption, and ammonia and carbon dioxide recovery section 30 which will be described hereinafter. The reactor 11 operates adiabatically at a temperature between about 180 C. and about 195 C. and at a pressure between about 180 atmospheres gauge and about 240 atmospheres gauge. The gaseous carbon dioxide fed to the reactor reacts instantaneously and totally with the stoichiometric amount of ammonia to form ammonium carbamate. The exothermic heat of reaction is utilized to adiabatically maintain the reactor mixture at the reaction temperature. The reactor etlluent which contains urea, unreacted ammonium carbamate, excess ammonia, water, and air completely dissolved in the reactor etlluent solution is delivered through pipe 27, pressure control valve 28, and pipe 29 into the recovery unit 30 wherein the unreacted carbamate is decomposed to carbon dioxide and ammonia which are separated from the urea solution. The urea solution is discharged through pipe 32. Ammonia and carbon dioxide are thereafter recondensed to ammonium carbamte which is redissolved in water with part of the excess ammonia and is recycled for complete utilization back into reactor 11 through pipe 31, carbamate pump 34, and pipe 35. The remaining portion of excess ammonia is recycled back through pipe 33 into pipe 12 to join the main stream of fresh liquid ammonia fed into the reactor.
'I'he material of which the urea synthesis equipment is constructed is stainless steel or other chromium-nickel steels containing, for instance, from 16% to 20% of chromium, 8% to 14% of nickel, and 1.75% to 4% of molybdenum and zirconium.
The following more specific examples serve to illustrate the present invention in detail without, however, limiting the same thereto.
EXAMPLE 1 Procedure according to U.S. Patent No. 2,727,069
The following amounts per hour of reaction components are introduced into reactor 11:
(a) A mixture of 12,400 parts of carbon dioxide and 117 parts of air corresponding to 27 parts of oxygen and 90 parts of nitrogen is introduced into the compressor 2, compressed therein to a pressure of about 210 atmospheres gauge, and after cooling in after-cooler 4 to 90 C. and de-oiling in oil separator 8, is introduced into reactor 11.
(b) Simultaneously 20,650 parts of liquid ammonia are pumped into reactor 11 through heater 15 wherein the ammonlia is heated to 90 C.
(c) 23,150 parts of an ammonium carbamate solution as it is recovered from the recovery unit 30 at 90 C., is recycled into reactor 11.
The three components are reacted in reactor 11 at a temperature of 190 C. and a pressure of 210 atmospheres gauge.
The reactor eflluent consists of a gaseous phase of the following composition:
The gaseous 'and liquid reactor effluents :are delivered to the ammonia-carbon dioxide recovery section 30.
The recondensed ammonium carbamate solution which is recycled from the recovery section 30 to the reactor 11 is composed of Parts Carbon dioxide 7,400 Ammonia 9,950 Water 5,800
Total 23,150
Excess ammonia recovered from the recovery section 30 1s recycled through pipe 33 to the ammonia feed pipe 12.
The oxygen ratio in the reaction mixture is moles O2 3 1000 moles CO2- The reactor effluent has NH3 a. molar ratio of CO2 4 and H2O a molar ratio of -0.72
whereby the synthesis water is excluded.
The conversion rate is 62%. The iron content of the reactor etlluent is 0.4 ppm. and the turbidity is p.p.m. APHA Standard.
Thus, a ratio of three moles of oxygen to 1000 moles of carbon dioxide, corresponding to 0.3%, by volume, of oxygen calculated for carbon dioxide freshly introduced into the apparatus yields a urea product of a satisfactory iron content 4but of a relatively high turbidity and with a relatively low conversion rate.
EXAMPLE 2 Procedure according to the present invention The following amounts per hour of reaction components are introduced into reactor 11:
(a) 12,400 parts of carbon dioxide, compressed to a pressure of 210 atmospheres gauge and cooled to 65 C. are introduced into reactor 11. y
(b) A mixture of 19,520 parts of liquid ammonia mixed, after heating to 70 C., with 28,0 parts of air, i.e. 21.6 parts of nitrogen and 6.4 parts of oxygen, compressed and cooled to 70 C., is introduced into the reactor 11.
(c) An ammonium carbamate solution of Y Parts Carbon dioxide 5,200 Ammonia 7,680 Water 5,050
Total of 17,930
as recovered from the recovery section 30 at 88 C., is recycled into the reactor 11.
The reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
The reactor eiliuent is a liquid of the following composition:
Said liquid eiuent is delivered to the ammonia-carbon dioxide recovery section 30.
Excess ammonia recovered from the recovery section 30 is recycled to the ammonia feed pipe 12 through pipe 33. The oxygen ratio in the reaction mixture is moles of O2 0 71 1000 moles of fresh CO2- The reactor eiuent has NH3 a molar rat-1o of CO2 4 and H2O a molar rat1o of 0 0-2-071 thereby excluding the synthesis Water.
The conversion rate is 70%. The iron content of the reactor eluent is 0.5 p.p.m. and the turbidity is 35 p.p.m. APHA Standard.
Thus when proceeding according to the present invention and introducing 0.7 mole of oxygen per 1000 moles of carbon dioxide into the reactor, the conversion rate is appreciably higher, namely about 13% higher, and the turbidity of the resulting urea solution is Within the commercially acceptable range of about 35 p.p.m. APHA Standard in comparison to the lower conversion rate and the considerably higher turbidity of the urea solution produced according to Example 1 with a considera'bly higher oxygen ratio. The corrosion rate of the urea synthesis apparatus walls is also very low and about as low as when admixing larger amounts of oxygen and the iron content of the reactor eluent is about the same as that of Example 1.
EXAMPLE 3 Procedure according to U.S. Patent No. 3,137,724
The following amounts per hour of reaction components are introduced into reactor 11:
(a) A mixture of 12,400 parts of carbon dioxide and 7.8 parts of air corresponding to 6.0 parts of nitrogen and 1.8 parts of oxygen, is introduced into the compressor 2, compressed therein to a pressure of 320 atmospheres gauge, and after cooling to 60 C. in aftercooler 4 and de-oiling in oil separator 8, is introduced into reactor 11.
(b) Simultaneously 20,120 parts of liquid ammonia are pumped into the reactor 11 through heater 15, Wherein the ammonia is heated to 100 C.
(c) An ammonia carbamate solution of as recovered from the recovery section 30 at 90 C., is recycled into the reactor 11.
8 The reaction temperature is 200 C. and the reaction pressure 320 atmospheres gauge.
The liquid reactor efuent is composed as follows:
Parts Urea 16,800 Carbon dioxide 4,840 Ammonia 17,000 Water 8,740 Air 7.8
Total 47,387.8
Said euent is delivered to the ammonia-carbon dioxide recovery section 30.
IExcess ammonia recovered from the recovery section 30 is recycled to the ammonia feed pipe 12. through pipe 33.
The oxygen ratio in the reaction mixture is moles O2 0 2 1000 moles CO2- The reactor effluent has a. molar ratio of and thereby excluding the synthesis water.
The conversion rate is 72%. The iron content of the reactor effluent is 15 p.p.m. and the turbidity is 20 p.p.m. APHA Standard.
Thus, when further reducing the oxygen content to an oxygen ratio below 0.5 and operating at a higher pressure and temperature as disclosed in U.S. Patent No. 3,137,- 724, the conversion rate is only slightly increased over that of Example 2, mainly because of less water present in the reactor. The corrosion rate of the urea synthesis reactor walls, however, is increased by a factor of about 30, namely to 15 p.p.m., in contrast to 0.5 p.p.m. according to Example 2, i.e. to an extent which is prac tically not acceptable.
EXAMPLE 4 Procedure according to the present invention Parts Carbon dioxide 5,720 Ammonia 7,700 Water 4,460
Total 17,880
is recovered from the recovery section 30 at 88 C. and recycled into the reactor 11.
The reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
The liquid reactor eiuent is composed of Parts Urea 16,800 Ammonium carbamate 10,281 Ammonia 12,599 Water u 9,500 Air 27 Total liquid effluent 49,207
Said efuent is delivered to the ammonia-,carbon dioxide recovery section 30. l p
Excess ammonia recovered from the recovery section 30 is recycled to the ammonia feed pipe 12 through thereby excluding the synthesis water.
The conversion rate is 68%. The -iron content of thereactor eiiiuent is 0.5 p.p.m. and the turbidity is 30 p.p.m. APHA Standard.
This example, like Example 2, also shows that by proceeding according to the present invention the conversion rate is considerably increased and the turbidity is markedly decreased compared iwith the respective data obtained when proceeding according to 'Example 1, i.e. according to U.S. 'Patent No. 2,727,069', while compared with the procedure according to U.S. Patent No. 3,137,- 724 the anticorrosive effect is many times improved.
rEXAMPLE Procedure according to U.S. -Patent No. 3,137,724 but at a lower temperature and pressure The following amounts per hour of reaction components are introduced into reactor 11:
(a) A mixture of 12,400 parts of carbon dioxide and 7.8 parts of air corresponding to 6.0 parts of nitrogen and 1.8 parts of oxygen, is introduced into the compressor 2, compressed therein to va pressure of 210 atmospheres gauge, and after cooling to 65 C. in after-cooler 4 and de-oiling in oil separator 8, is introduced into reactor 11.
10 The reactor effluent is 4composed as follows: n
. y Parts Urea 16,800 Carbon dioxide 5,280 Ammonia 17,680 Water 10,090 Air g 7.8
Total 49,875.8 Said eiluent is delivered to the ammonia-carbon dioxide recovery section 30.
Excess ammonia recovered from the recovery section 30 is recycled to the ammonia feed pipe 12 through pipe 33.
The oxygen ratio in the reaction mixture is moles O2 0 2 1000 moles CO2- The reactor eluent has NH3 a molar ratio of CO2-4 and H2O a molar ratio of -Cz 0.71
thereby excluding the synthesis water.
The conversion rate is The iron content of the reactor effluent is l5 p.p.m. and the turbidity is 20 p.p.m. APHA Standard.
Thus when proceeding according to U.S. Patent No. 3,137,724 with a low oxygen ratio and reducing the reaction pressure and temperature to that employed according to the present invention, the corrosion rate is increased very considerably to 15 p.pm. while the conversion rate is not substantially increased over that obtained in Example 2, i.e. when proceeding according to the present invention.
The following table clearly shows the superior results achieved, when proceeding according to the present invention, in comparison with the results obtained according to the prior art.
Reactor Molar ratio Turbidity Conver- Iron p.p.m., Tempera- Pressure, Oxygen NH3] HZO/ sion rate, content, APHA ture, C. atm. gauge ratio l CO2 CO2 percent p.p.m. Standard Example Number:
moles O2 l Oxygen ratio=* 1,000 moles CO2 (b) Simultaneously 19,520 parts of liquid ammonia are I claim:
pumped into the reactor 11 through heater 15 wherein the ammonia is heated to 70 C.
(c) An ammonium carbamate solution of as recovered from the recovery section at y88 C., is recycled int the reactor 11.
The reaction temperature is 190 C. and the reaction pressure 210 atmospheres gauge.
(b) said oxygen being admixed in an amount between about 0.6 mole and about 0.85 mole of oxygen per 1000 moles of carbon dioxide, whereby y (c) the ratio of ammonia to carbon dioxide in the reactor is between about 3.5-4.2 moles of ammonia. to 1 mole of carbon dioxide and (d) the ratio of water to carbon dioxide in the reactor moles of carbon dioxide and the reaction is carried out is between about 0.5-0.7 mole of water to 1 mole at about 190 C. and a pressure of about 210 atmospheres of carbon dioxide, whereby gauge. (e) the reaction is carried out at a temperature be- 4. The process of producing urea according to claim 2, tween about 185 C. and about 195 C. and 5 wherein the oxygen is admixed in an amount between (f) at a pressure between about 1.80 atmospheres gauge about 0.68 mole and about 0.70 mole of oxygen per 1000 and about 240 atmospheres gauge, and whereby moles of carbon dioxide and the reaction is carried out (g) unreacted carbamate is recovered from the eiuent at about 190 C. and a pressure of about 210 atmospheres of the reactor and is gauge. (h) recycled as an aqueous ammoniacal carbamate 10 References Cited solution to the reactor. UNITED STATES PATENTS 2. The process of producing urea according to claim 1, 2,680,766 6/1954 De Ropp 260 555 wherein the oxygen is supplied in the form of air.
3. The process of producing urea according to claim 1, 15 BERNARD HELFIN, Primal-y Examiner 'wherein the oxygen is admixed in an amount between about 0.68 mole and about 0.07 mole of oxygen per 1000 M W' GLYNN Assistant Exammer
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US78705968A | 1968-12-26 | 1968-12-26 |
Publications (1)
Publication Number | Publication Date |
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US3574738A true US3574738A (en) | 1971-04-13 |
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ID=25140303
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US787059A Expired - Lifetime US3574738A (en) | 1968-12-26 | 1968-12-26 | Process of synthesizing urea |
Country Status (7)
Country | Link |
---|---|
US (1) | US3574738A (en) |
JP (1) | JPS4832092B1 (en) |
BE (1) | BE765599A (en) |
DE (1) | DE2116552A1 (en) |
FR (1) | FR2132535B1 (en) |
GB (1) | GB1293307A (en) |
NL (1) | NL7104624A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4758311A (en) * | 1982-06-03 | 1988-07-19 | Montedison S.P.A. | Method for avoiding the corrosion of the strippers in the urea manufacturing plants |
US10975022B2 (en) * | 2017-11-10 | 2021-04-13 | Stamicarbon B.V. | Urea production process and plant |
-
1968
- 1968-12-26 US US787059A patent/US3574738A/en not_active Expired - Lifetime
-
1969
- 1969-04-14 JP JP44028330A patent/JPS4832092B1/ja active Pending
-
1971
- 1971-03-25 GB GB8222/71A patent/GB1293307A/en not_active Expired
- 1971-04-05 DE DE19712116552 patent/DE2116552A1/en active Pending
- 1971-04-06 NL NL7104624A patent/NL7104624A/xx unknown
- 1971-04-07 FR FR7112364A patent/FR2132535B1/fr not_active Expired
- 1971-04-09 BE BE765599A patent/BE765599A/en unknown
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4758311A (en) * | 1982-06-03 | 1988-07-19 | Montedison S.P.A. | Method for avoiding the corrosion of the strippers in the urea manufacturing plants |
US10975022B2 (en) * | 2017-11-10 | 2021-04-13 | Stamicarbon B.V. | Urea production process and plant |
Also Published As
Publication number | Publication date |
---|---|
DE2116552A1 (en) | 1972-10-12 |
FR2132535B1 (en) | 1976-06-18 |
BE765599A (en) | 1971-08-30 |
GB1293307A (en) | 1972-10-18 |
FR2132535A1 (en) | 1972-11-24 |
NL7104624A (en) | 1972-10-10 |
JPS4832092B1 (en) | 1973-10-04 |
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